Air-Guiding Carrier Type Wind Power Collection Device

ABSTRACT

An air-guiding carrier type wind power collection device includes a floating body and two air guiding tubes. The floating body includes a compartment filled with an uprising gas having a density lower than that of air. The floating body includes a floating assembly controlling a pressure and a temperature of the uprising gas received in the compartment. The air guiding tubes extend through the compartment of the floating body. Each air guiding tube has an air inlet and an air outlet. The air outlet includes a peripheral wall having a windward section and a guiding section. The peripheral wall has a cutout portion formed between the windward section and the guiding section. An air channel is formed between and in communication with the air inlet and the air outlet of each air guiding tube. A wind power generating assembly is mounted in each of the air channels.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to an above-ground type wind powercollection device and, more particularly, to an air-guiding carrier typewind power collection device that can stably stay in the air whileproviding enhanced wind power generating efficiency.

2. Description of the Related Art

Regardless of using either horizontal or vertical shaft type wind powergenerators, the performance of current wind power generation is affectedby the installation site. When mounted on the ground, the electricityoutput of the wind power generators is greatly affected by theatmospheric boundary layer flow due to the terrain. By comparison, theatmospheric flow in the upper air has a static wind velocity and strongwind. Thus, devices or systems capable of staying in the air are anotheroption of current development of offshore wind power generation.Currently, horizontal shaft type wind power generators utilizing theupper air current include a tower or column structure that has a highmanufacturing cost and that is difficult to maintain and repair whilehaving a limitation to the height of the tower or column structure.Thus, it is impossible to timely adjust the height of the wind powergenerator or the windward face responsive to the changeable upper-airclimate. As a result, when the wind in the upper air is either too smallor too strong and changes its direction, the normal energy transmissionmechanism of the wind power generator will be adversely affected,failing to provide the required generating efficiency.

Nowadays, air-floating carriers, such as flying boats and balloons, aredeveloped to carry generating mechanisms to the upper air for collectingthe wind power to generate electricity that is subsequently transmittedto the ground. Such development is an important option for use ofrecycled energy. As an example, when a commercial airplane equipped witha small turbofan looses its power, electricity can be generated by therelative speed and can be used in navigation or a communication system.The literature also discloses that a flying boat can be equipped with awind power generating device so that the wind power generating devicecan obtain the required wind power for normal operation when the flyingboat is in the upper air. Thus, the wind energy can be used forgenerating electricity.

Since the wind power generating device mounted to a flying boat dependson a large fan that is mounted to an outer side of the flying boat so asto be driven by the strong wind in the upper air for generatingelectricity. However, the large fan requires large power to drive thevanes of the fan. Namely, strong wind in the upper air is required forgenerating electricity. Continuous generation of electricity can not bemaintained, leading to low generating efficiency and ineffective use ofwind energy in the upper air.

Furthermore, the direction of the air currents in the upper air ischangeable, causing violent wobbling of the carrier carrying the windpower generating device and adversely affecting normal operation of thewind power generating device. Thus, it is difficult to collect and usethe abundant wind energy in the upper air in a stable state and at astable height. The application values of conventional techniques ofair-floating carriers are not satisfactory. As a result, air-floatingcarriers can not completely replace conventional tower or column typewind power generating mechanisms, which is an extreme waste of theabundant wind energy in the upper air.

Thus, to solve the above-mentioned disadvantages, a need exists for anovel wind power collection device that can effectively collect and usethe energy of the strong wind in the upper air while stably staying at asuitable height in the upper air having steady strong wind.

SUMMARY OF THE INVENTION

An objective of the present invention is to solve the above-mentioneddisadvantages by providing an air-guiding carrier type wind powercollection device that can effectively collect the wind energy by usingthe characteristics of the upper air, increasing the velocity anddensity of the air current in the upper air to increase the wind powergenerating efficiency.

Another objective of the present invention is to provide an air-guidingcarrier type wind power collection device that can reduce the adverseeffect by the resistance and the directional change of the air currentin the upper air by using an aerodynamic configuration like an aircraft,so that the wind power collection device can stably stay at a suitableheight in the upper air.

A further objective of the present invention is to provide anair-guiding carrier type wind power collection device that can utilize atemperature difference to create a floating effect for activelyadjusting the height, so that the wind power collection device can stayat the suitable height in the upper air.

The present invention fulfills the above objectives by providing anair-guiding carrier type wind power collection device including afloating body and two air guiding tubes. The floating body includes acompartment filled with an uprising gas having a density lower than thatof air. The floating body includes a floating assembly controlling apressure and a temperature of the uprising gas received in thecompartment. The air guiding tubes extend through the compartment of thefloating body. Each air guiding tube has an air inlet and an air outletat two ends thereof outside the compartment. The air outlet of each airguiding tube includes a peripheral wall having a windward section and aguiding section. The peripheral wall of the air outlet has a cutoutportion formed between the windward section and the guiding section. Anair channel is formed between and in communication with the air inletand the air outlet of each air guiding tube. A wind power generatingassembly is mounted in each of the air channels.

The floating body includes an air-guiding portion having a main axiscorresponding to the air inlets of the two air guiding tubes. Theair-guiding portion includes arcuate cross sections perpendicular to alongitudinal axis along which the floating body extends. The air-guidingportion has a streamlined outline extending from an outer periphery ofthe floating body and imitating an airplane fuselage. The floatingassembly includes a pressure resistant body and a temperaturecontrolling unit connected to the pressure resistant body. Thetemperature controlling unit controls a temperature of a gas received inthe pressure resistant member. The pressure resistant member includes anouter periphery, with an insulating layer provided on the outerperiphery of the pressure resistant member to prevent heat loss.

The pressure resistant member is mounted in the compartment of thefloating body. The pressure resistant member includes a chamberreceiving an uprising gas the same as the uprising gas in thecompartment. The uprising gas is in a high temperature/high pressurestate. The pressure resistant member further includes a plurality of gascontrolling units mounted to a peripheral wall of the pressure resistantmember for controlling exchange of the uprising gas in the chamber andthe uprising gas in the compartment. The temperature controlling unit isconnected to the floating body and mounted to an outer periphery of thefloating body. The temperature controlling unit includes a plurality ofsolar plates and a heating member connected to the plurality of solarplates, with the heating member extending into the chamber of thepressure resistant member. Furthermore, the floating body furtherincludes a support having first and second ends. The first end of thesupport is fixed to a bottom side of the floating body. The second endof the support is adapted to be fixed to a ground. The support draws thefloating body and includes a steel rope containing a cable.

The wind power generating assembly includes a vane unit and a generator.The vane unit is mounted in the air channel and located in the reducedsection. The generator is connected to the vane unit by a transmissionshaft located in the compartment of the floating body. The cutoutportion forms the guiding section, with an uncut portion of theperipheral wall of the air outlet forming the windward section. A localhigh pressure area is formed on a surface of the windward section whenambient air flows through the windward section, and a local low pressurearea is formed at the guiding section when the ambient air flows fromthe local high pressure area to the guiding section, thereby increasingthe air inlet amount.

Moreover, a plurality of pairs of ailerons is provided on a lateralperiphery of the floating body. The plurality of pairs of ailerons W isrespectively arranged at middle and rear sections of the floating body.A swayable rudder further is provided on each aileron.

The present invention will become clearer in light of the followingdetailed description of illustrative embodiments of this inventiondescribed in connection with the drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

The illustrative embodiments may best be described by reference to theaccompanying drawings where:

FIG. 1 shows a perspective view of an air-guiding carrier type windpower collection device according to the present invention.

FIG. 2 shows a cross sectional view of the air-guiding carrier type windpower collection device according to the present invention.

FIG. 3 is a perspective view illustrating operation of the air-guidingcarrier type wind power collection device according to the presentinvention.

FIG. 4 is a cross sectional view illustrating operation of theair-guiding carrier type wind power collection device according to thepresent invention.

FIG. 5 is a perspective view illustrating controlling of the air-guidingcarrier type wind power collection device according to the presentinvention.

All figures are drawn for ease of explanation of the basic teachings ofthe present invention only; the extensions of the figures with respectto number, position, relationship, and dimensions of the parts to formthe preferred embodiments will be explained or will be within the skillof the art after the following teachings of the present invention havebeen read and understood. Further, the exact dimensions and dimensionalproportions to conform to specific force, weight, strength, and similarrequirements will likewise be within the skill of the art after thefollowing teachings of the present invention have been read andunderstood.

Where used in the various figures of the drawings, the same numeralsdesignate the same or similar parts. Furthermore, when the terms“first”, “second”, “lower”, “upper”, “inner”, “outer”, “side”,“portion”, “section”, “front”, “middle”, “rear”, “longitudinal”,“axial”, “vertical”, “height”, and similar terms are used herein, itshould be understood that these terms have reference only to thestructure shown in the drawings as it would appear to a person viewingthe drawings and are utilized only to facilitate describing theinvention.

DETAILED DESCRIPTION OF THE INVENTION

FIGS. 1 and 2 illustrate an embodiment of an air-guiding carrier typewind power collection device according to the present invention.According to the form shown, the air-guiding carrier type wind powercollection device includes a floating body 1 and two air guiding tubes 2mounted to different sections of the floating body 1.

The floating body 1 is a soft object, such as a rubber balloon.Preferably, the floating body 1 is a plastic soft object with anaerodynamic configuration of an airplane and is filled with an uprisinggas having a density smaller than the air. Preferably, the floating body1 is filled with helium to provide the floating body 1 with suitablefloating force to float in the air. Specifically, the floating body 1includes a compartment 11 receiving the uprising gas at normaltemperature/normal pressure to create strong floating force for keepingthe floating body 1 in the air. In this embodiment, the floating body 1includes an air-guiding portion 12 having a main axis corresponding tothe air inlets of the two air guiding tubes 2. The air-guiding portion12 includes arcuate cross sections perpendicular to a longitudinal axisX along which the floating body 1 extends (see FIG. 2). In thisembodiment, the air-guiding portion 12 is similar to a nose cone of anairplane. Particularly, the air-guiding portion 12 preferably has astreamlined outline extending from an outer periphery of the floatingbody 1 and imitating an airplane fuselage to reduce resistance to thefloating body 1 while guiding a large amount of upper air into the airguiding tubes 2. A plurality of pairs of ailerons W may be furtherprovided on a lateral periphery of the floating body 1. In thisembodiment, the plurality of pairs of ailerons W consists of a firstpair of ailerons W and a second pair of ailerons W. The first pair ofailerons W is preferably similar to flaps of an airplane and arranged ona middle section of the floating body 1. The second pair of ailerons Wis preferably similar to horizontal tail wings of an airplane andarranged on a rear section of the floating body 1. Additionally, anaileron W similar to a vertical tail wing of an airplane may be providedon the periphery of the floating body 1 at the rear section of thefloating body 1. The ailerons W may create the necessary uprising forcewhile reducing adverse effect to the floating body 1 resulting from thewind force and directional change in the upper air, allowing thefloating body 1 to stably stay in the upper air. In the embodiment, aswayable rudder H may be further provided on each of the ailerons W forcontrolling the movement of the floating body 1 in the upper air,assuring the air inlets of the air guiding tubes 2 to face the flowingdirection of the air current in the upper air. The floating body 1 maybe divided into two sections by a plane formed by the longitudinal axisX. One of the sections containing the air-guiding portion 12 is made ofrigid material to stabilize the air current flowing through theair-guiding portion 12, thereby reducing the air resistance and avoidingseparation of the boundary layer flow as well as turbulence.

Furthermore, the floating body 1 includes a floating assembly 13 tocontrol the pressure and temperature of the uprising gas in thecompartment 11. The floating assembly 13 includes a pressure resistantmember 131 and a temperature controlling unit 132 connected to thepressure resistant member 131. The temperature controlling unit 132provides heat to a gas to be filled into the pressure resistant member131.

In this embodiment, the pressure resistant member 131 is mounted in thecompartment 11 of the floating body 1 and includes a chamber R receivingan uprising gas the same as that received in the compartment 11.Preferably, the chamber R is filled with high temperature/high pressurehelium for adjusting the pressure and temperature of the gas in thecompartment 11, achieving better efficiency in adjustment of thepressure and temperature of the gas in the compartment 11. The pressureresistant member 131 further includes a plurality of gas controllingunits V mounted to a peripheral wall of the pressure resistant member131 so as to communicate the chamber R of the pressure resistant member131 with the compartment 11 of the floating body 1, allowing gasexchange between the chamber R and the compartment 11. The pressureresistant member 131 can be any container made of a material capable ofresisting high temperature and high pressure and is preferably made oflightweight steel article of manufacture to resist the impact of thehigh temperature/high pressure gas. Particularly, the pressure resistantmember 131 can be configured corresponding to the outline of thefloating body 1. Furthermore, the outer periphery of the pressureresistant member 131 preferably provides thermally insulating effect,such as by providing an insulating layer (not shown) on the outerperiphery of the pressure resistant member 131 to avoid heat loss in thechamber R. Further, the gas controlling units V can be connected tosensor activators, pumps, or the like to achieve gas exchange betweenthe chamber R and the compartment 11, which can be appreciated by oneskilled in the art and detailed description of which is not given toavoid redundancy.

The temperature controlling unit 132 is connected to the floating body 1and preferably mounted to the outer periphery of the floating body 1 forsupplying heat to the gas filled in the pressure resistant member 131.The temperature controlling unit 132 can be fixed to a top face (seeFIG. 1) of the floating body 1 by such as bonding, gluing, etc.Preferably, the temperature controlling unit 132 is comprised of aplurality of solar plates arranged in a matrix. The solar platesdirectly absorb the solar energy and convert it into electricity andheat energy that can be utilized when desired, enhancing the absorbingefficiency of the solar energy. Further, the temperature controllingunit 132 is connected to the chamber R of the pressure resistant member131 and heats the gas in the chamber R with the heat energy convertedfrom the solar energy absorbed by the temperature controlling unit 132.The temperature controlling unit 132 can be of any type and shape. As anexample, a heating member (not shown) can be connected to the solarplates and extends into the chamber R of the pressure resistant member131 and abuts with the inner periphery of the pressure resistant member131, increasing the heating efficiency of the chamber R of the pressureresistant member 131 by the temperature controlling unit 132.

Furthermore, the floating body 1 can include a support 14 connected tothe ground for drawing the floating body 1. Preferably, the support 14includes a steel rope containing a cable (not shown) and fixed to abottom side of the floating body 1 (FIG. 2). Thus, the electricityconverted from the wind power can be transmitted by the cable to theground for use.

The air guiding tubes 2 are hollow tubes in the form of chimneys. Theair guiding tubes 2 extend through the compartment 11 of the floatingbody 1 from upper surface to lower surface of the floating body 1. Eachair guiding tube 2 has an air inlet 21 and an air outlet 22 on two endsthereof outside the compartment 11. The air inlet 21 faces theair-guiding portion 12 of the floating body 1. The air inlet 21 and theair outlet 22 are in communication with an air channel 23 inside the airguiding tube 2. The air channel 23 allows passage of upper air current.In this embodiment, the air outlet 22 of the air guiding tube 2 includesa peripheral wall having a windward section 221 and a guiding section222. The windward section 221 and the guiding section 222 have an airpressure difference therebetween to create a stack effect, increasingthe air inlet amount.

The peripheral wall of the air outlet 22 preferably has a cutout portionformed between the windward section 221 and the guiding section 222,with the uncut portion of the peripheral wall forming the windwardsection 221, and with the cutout portion forming the guiding section222. Thus, when the ambient air flows through the windward section 221,a local high pressure area A is formed on the surface of the windwardsection 221. When the ambient air flows from the local high pressurearea A to the guiding section 222, a local low pressure area B is formedat the guiding section 222. Due to the pressure difference between thelocal high pressure area A and the local low pressure area B, the aircurrent flowing through the guiding section 222 generates a vortex pairand creates the stack effect at the air outlet 22, driving the air outof the air channel 23 and, hence, providing a rapid wind collectingeffect.

Furthermore, the air channel 23 can include a reduced section 231between the air inlet 21 and the air outlet 22. The reduced section 231has the minimum cross sectional diameter in the air channel 23. Thereduced section 231 is formed by gradually reducing the inner diameterof the air guiding tube 2 to form an hourglass-shaped structure.Specifically, the inner diameter of the air guiding tube 2 graduallydecreases from the air inlet 21 towards the reduced section 231 and thengradually increases from the reduced section 231 towards the air outlet22 where a restoration area is formed. By such an arrangement, the windcollecting effect of the air channel 23 can be increased. The flow rateof the air current flowing from the air inlet 21 through the air outlet22 is increased. Thus, a large amount of air can flow through the airchannel 23 in a short period of time.

With reference to FIG. 2, a wind power generating assembly 24 is mountedin the air channel 23 of each air guiding tube 2 for utilizing the windenergy of the upper air collected by the air guiding tube 2. In thisembodiment, the wind power generating assembly 24 includes a van unit241 and a generator 242. The vane unit 241 is mounted in the air guidingtube 2 and preferably in the reduced section 231 to increase therotating speed of the vane unit 241 for outputting the shaft workthrough the air current that is accelerated while flowing through thereduced section 231. The vanes of the vane unit 241 is preferablylocated in a direction easily receiving the wind to use the high-speedair current in the air channel 23 to drive the vanes of the vane unit241 to rotate at high speed, generating mechanical energy in the form ofshaft work. The generator 242 is connected to the vane unit 241 by atransmission shaft that is preferably located outside of the path of theair current in the air channel 23. Particularly, the transmission shaftcan be mounted in the compartment 11 of the floating body 1 or to theouter periphery of the floating body 1 to avoid an increase in theresistance to the airflow if the transmission shaft were mounted in theair channel 23. By such an arrangement, the air current can be rapidlyguided into the air channel 23 and drives the vane unit 241 to generatemechanical energy that is converted by the generator 242 intoelectricity, effectively utilizing the natural wind in the upper air togenerate electricity. Furthermore, the vane unit 241 can be used as anauxiliary air pump when the ambient air is insufficient. Specifically,the vane unit 241 can be activated to increase the flow rate of theupper air current entering the air guiding tube 2, maintaining the airguiding tube 2 in the best state for receiving air current. Thus, thegenerator 242 can continuously generate electricity in the upper air.

With reference to FIGS. 3 and 4, in use of the air-guiding carrier typewind power collection device according to the present invention, thecompartment 11 of the floating body 1 is filled with normaltemperature/normal pressure helium, and the chamber R of the pressureresistant member 131 is filled with high temperature/high pressurehelium. Since the density of helium is lower than the air and since thetemperature of the helium in the floating body 1 is higher than theambient air, the carrier is provided with floating force and, thus,moves into the upper air, with the support 14 drawing the carrier to asuitable floating direction in the upper air. The ailerons W on thefloating body 1 imitating an airplane fuselage provide the floating body1 with stability and uprising force to stay in the upper air. Throughadjustment and controlling of the floating assembly 13 to balance thetemperature and pressure of the uprising gas in the compartment 11 ofthe floating body 1 to keep a suitable temperature difference betweenthe compartment 11 and the ambient air, the floating body 1 can stablystay in the upper air having strong wind and high velocity.

While the floating body 1 stably stays in the upper air, the upper aircurrent flows from the air-guiding portion 12 along the floating body 1imitating a streamlined fuselage of an airplane into the air guidingtubes 2. Furthermore, since the windward sections 221 formed at the airoutlets 22 of the air guiding tubes 2 face the flowing direction of theincoming ambient air current, the ambient air current flows through eachwindward section 221 and forms the local high pressure section A on eachwindward section 221. Due to the air pressure gradient, the air currentat the local high pressure section A is automatically accelerated whileflowing through the cutout portion of each air outlet 22, therebycreating the local low pressure section B on the guiding section 222 ofthe air outlet 22 of each air guiding tube 2. Separation of the boundarylayer flow of the air current finally occurs at each guiding section222, leading to generation of vortex airflow at each guiding section222. Since a stack effect is obtained due to the pressure differencebetween the air outlet 22 and the air channel 23, the air currentflowing through the air channel 23 of each air guiding tube 2 canrapidly exit the air guiding tube 2, and a large amount of air airflowscontinuously enters the air inlet 21 of each air guiding tube 2. Thisallows rapid flowing of the air current in each air channel 23. Underthe law of conservation of energy and mass, the air current isaccelerated while passing through the reduced section 231 of each airchannel 23, so that the single-stage or multi-stage vanes of the vaneunit 241 in each air guiding tube 2 can directly be driven by strong aircurrent to rotate, generating mechanical energy that is converted by thegenerator 242 into electricity. Effective use of the wind energy in theupper air for generating electricity is thus achieved.

With reference to FIG. 5, when the air-guiding carrier type wind powercollection device according to the present invention is subjected to achangeable climate in the upper air, the floating body 1 can becontrolled to roll, tilt, and sway through control of the rudders H onthe ailerons W. Thus, the air-guiding carrier type wind power collectiondevice according to the present invention can stably float in the upperair and continuously draws in air current in response to variousenvironments having changeable upper-air climates, changeable windpowers, and changeable wind directions, achieving enhanced wind powergenerating efficiency in the upper air. As an example, the rudders H onthe ailerons W can be controlled to sway up and down so as to controlthe floating body 1 to roll (see route D1 in FIG. 5). As anotherexample, the rudders H on the ailerons W can be controlled to sway upand down so as to control the floating body 1 to tilt (see route D2 inFIG. 5). As a further example, the rudders H on the ailerons W can becontrolled to sway up and down so as to control the floating body 1 torock (see route D3 in FIG. 5). The operation to control the rudders H onthe ailerons W of the airplane-shaped structure can be appreciated byone skilled in the art, detailed description of which is, thus, omittedto avoid redundancy.

In view of the foregoing, through use of the air guiding tubes 2 on thefloating body 1 of the air-guiding carrier type wind power collectiondevice according to the present invention, a stack effect can be createdin the air outlet 22 of each air guiding tube 2 when the floating body 1rises to the upper air area having strong wind energy, increasing theefficiency in guiding the upper air current into each air guiding tube2. At the same time, through the air-guiding portion 12 imitating thestreamlined fuselage of an airplane along the floating body 1, thehigh-speed airflow in each air channel 23 impacts the vane unit 241 anddrives the single-stage or multi-stage vanes of the vane unit 241 torotate, generating mechanical energy that is converted by the generator242 into electricity. Thus, the wind power generating efficiency in theupper air is increased. Furthermore, through provision of the floatingassembly 13 in the floating body 1 and timely gas exchange between thecompartment 11 and the chamber R, the height of the wind powercollection device according to the present invention can be activelyadjusted to maintain the temperature difference between the gas in thecompartment 11 and the ambience, stably keeping the wind powercollection device according to the present invention in the upper airhaving strong wind so as to collect the abundant wind energy.

In the air-guiding carrier type wind power collection device accordingto the present invention, the wind energy in the upper air caneffectively be collected and used to increase the velocity and densityof the air current, increasing the wind power generating efficiency.

In the air-guiding carrier type wind power collection device accordingto the present invention, the adverse effect by the strong wind anddirectional change of the air current in the upper air can be avoided,and the wind power collection device can stably stay at a suitableheight in the upper air through active adjustment of the height.

Thus since the invention disclosed herein may be embodied in otherspecific forms without departing from the spirit or generalcharacteristics thereof, some of which forms have been indicated, theembodiments described herein are to be considered in all respectsillustrative and not restrictive. The scope of the invention is to beindicated by the appended claims, rather than by the foregoingdescription, and all changes which come within the meaning and range ofequivalency of the claims are intended to be embraced therein.

1. An air-guiding carrier type wind power collection device comprising:a floating body including a compartment filled with an uprising gashaving a density lower than that of air, with the floating bodyincluding a floating assembly, with the floating assembly controlling apressure and a temperature of the uprising gas received in thecompartment; and two air guiding tubes extending through the compartmentof the floating body, with each of the two air guiding tubes having anair inlet and an air outlet at two ends thereof outside the compartment,with the air outlet of each of the two air guiding tubes including aperipheral wall having a windward section and a guiding section, withthe peripheral wall of the air outlet having a cutout portion formedbetween the windward section and the guiding section, with an airchannel formed between and in communication with the air inlet and theair outlet of each of the two air guiding tubes, with a wind powergenerating assembly mounted in each of the air channels.
 2. Theair-guiding carrier type wind power collection device as claimed inclaim 1, with the floating body including an air-guiding portion, withthe air-guiding portion including a main axis corresponding to the airinlets of the two air guiding tubes, with the air-guiding portionincluding arcuate cross sections perpendicular to a longitudinal axisalong which the floating body extends, with the air-guiding portionhaving a streamlined outline extending from an outer periphery of thefloating body and imitating an airplane fuselage.
 3. The air-guidingcarrier type wind power collection device as claimed in claim 1, with aplurality of pairs of ailerons provided on a lateral periphery of thefloating body, with the plurality of pairs of ailerons respectivelyarranged at middle and rear sections of the floating body, with aswayable rudder further provided on each aileron.
 4. The air-guidingcarrier type wind power collection device as claimed in claim 1, withthe air channel in each of the two air guiding tubes including a reducedsection between the air inlet and the air outlet, with the reducedsection having a minimum cross sectional diameter in the air channel. 5.The air-guiding carrier type wind power collection device as claimed inclaim 4, with the wind power generating assembly including a vane unitand a generator, with the vane unit mounted in the air channel andlocated in the reduced section, with the generator connected to the vaneunit by a transmission shaft located in the compartment of the floatingbody.
 6. The air-guiding carrier type wind power collection device asclaimed in claim 1, with the cutout portion forming the guiding section,with an uncut portion of the peripheral wall of the air outlet formingthe windward section.
 7. The air-guiding carrier type wind powercollection device as claimed in claim 1, with a local high pressure areaformed on a surface of the windward section when ambient air flowsthrough the windward section, with a local low pressure area formed atthe guiding section when the ambient air flows from the local highpressure area to the guiding section.
 8. The air-guiding carrier typewind power collection device as claimed in claim 1, with the floatingassembly including a pressure resistant body and a temperaturecontrolling unit connected to the pressure resistant body, with thetemperature controlling unit controlling a temperature of a gas receivedin the pressure resistant member, with the pressure resistant memberincluding an outer periphery, with an insulating layer provided on theouter periphery of the pressure resistant member.
 9. The air-guidingcarrier type wind power collection device as claimed in claim 8, withthe pressure resistant member mounted in the compartment of the floatingbody, with the pressure resistant member including a chamber receivingan uprising gas the same as the uprising gas in the compartment, withthe uprising gas being in a high temperature/high pressure state. 10.The air-guiding carrier type wind power collection device as claimed inclaim 8, with the pressure resistant member further including aplurality of gas controlling units mounted to a peripheral wall of thepressure resistant member, with the plurality of gas controlling unitscontrolling exchange of the uprising gas in the chamber and the uprisinggas in the compartment.
 11. The air-guiding carrier type wind powercollection device as claimed in claim 8, with the temperaturecontrolling unit connected to the floating body and mounted to an outerperiphery of the floating body, with the temperature controlling unitincluding a plurality of solar plates and a heating member connected tothe plurality of solar plates, with the heating member extending intothe chamber of the pressure resistant member.
 12. The air-guidingcarrier type wind power collection device as claimed in claim 1, withthe floating body further including a support having first and secondends, with the first end of the support fixed to a bottom side of thefloating body, with the second end of the support adapted to be fixed toa ground, with the support drawing the floating body, with the supportincluding a steel rope containing a cable.